KR20160025364A - Smart grids distribute network system - Google Patents

Abstract

A smart grid distribution network system of the present invention comprises: a modem unit which comprises: a first slave model for transmitting a registration requesting packet (CJR) through a power line communication (PLC) to request an initial registration process; and a second slave model already registered; a data concentration unit (DCU) which comprises a master model for receiving the registration requesting packet transmitted by the first slave modem and processing a registration procedure and an SNMP agent; a DB server for receiving the position information and the power network information of the first slave modem or the second slave modem transmitted by the DCU through a wired and wireless network and saving and updating the position information and the power network information; and, a distribution GIS system for periodically bringing the position information and the power network information from the DB server to display the distribution network on a three-dimensional GIS map in real time.

Description

{SMART GRIDS DISTRIBUTE NETWORK SYSTEM}

More particularly, the present invention relates to an intelligent power distribution system, and more particularly, to a power concentrator (DCU), in which a location data of a modem for which a registration request is made during a modem registration process, , And transmits it to the DB server, stores it in the DB server and updates it automatically, and then intelligently displays the nationwide distribution chart by interlocking with the distribution GIS system. will be.

In general, PLC (Power Line Communication) is also referred to as power line communication. When a power line is plugged into a socket of a home or an office, it can use voice, data, and the Internet at high speed. It is possible to connect home network to connect devices.

When this technology is realized, the complicated data transmission path to the cable television network, the telephone line, and the optical communication network has been reduced to one power line. Installation is also simple because it requires only a separate device such as a modem or system that divides power and communication data.

In addition to Internet service and network construction, remote control of electric power line based intelligent home appliances, remote meter reading of meters and remote control of various electric machines are possible. There are still problems such as the limitation of the speed due to sending data in the power line and the interference phenomenon of the power network itself, but it is expected to be put into practical use soon.

On the other hand, conventionally, a distribution GIS (Geographic Information System) is used for the construction and maintenance of a distribution network. However, due to a method of manually inputting the location of a modem to be registered to a server by an administrator after building the distribution system, Not only did it take a lot of time, but also the maintenance was inconvenient.

Korean Patent Publication No. 10-2013-0033806

SUMMARY OF THE INVENTION It is an object of the present invention to provide a data concentrator which periodically receives location data of a modem for which a registration request is made during a modem registration process and distribution information for all routes through a PLC, And an intelligent distribution system can be displayed intelligently by interworking with the distribution GIS system after the system is transferred to the DB server and automatically stored and updated in the DB server.

According to an aspect of the present invention, there is provided an intelligent power distribution system comprising a first slave modem transmitting a registration request packet (CJR) through a power line communication (PLC) to request an initial registration process, A data concentrator (DCU) including a master modem and an SNMP agent for receiving the registration request packet transmitted by the first slave modem and processing a registration procedure; A DB server for receiving location information and power grid information of the first slave modem or the second slave modem transmitted from the data concentrator (DCU) through a wired / wireless network, storing and updating the received location information and power grid information; And a distribution GIS system for periodically bringing the location information and the power network information from the DB server to display a distribution plan on a three-dimensional GIS map in real time.

The present invention has a technical effect of securing the reliability of the power network communication and the electric power supply by positively utilizing it in the new installation and maintenance of the distribution network based on the distribution topology and signal information.

1 shows a configuration of an intelligent power distribution system according to the present invention.
FIG. 2 illustrates a registration process between a PLC modem and a DCU according to an embodiment of the present invention. Referring to FIG.
FIG. 3 shows an example in which the PLC modems registered according to the registration procedure of FIG. 2 are displayed on the layout of the three-dimensional GIS.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

1 shows a configuration of an intelligent power distribution system according to the present invention.

1, an intelligent power distribution system 100 according to the present invention includes a modem unit 110, a data concentrator (DCU) 120, a DB server 130, and a distribution GIS system 140, do.

The modem unit 110 includes a plurality of first to Nth modems 111 to N in the respective receivers to measure and store the energy consumption of the customer and to transmit the metered data to the data concentrator 120 In this case, the mutual between the modems and between the modems and the data concentrator (DCU) 120 transmits and receives the meter reading data through the power line communication (PLC).

Here, the first modem 111 to the Nth modem 11N use an AMR (Automatic Meter Reading) modem including the respective location information.

The data concentrator 120 receives the location and power network information from the first modem 111 to the Nth modem 11N and transmits the received information to the DB server 130 via the wired and wireless network 10 .

In this case, the wired / wireless network 10 can use, for example, a WAN (Wide Area Network), 3G, 4G, LTE, LTE-A, Wireless Broadband Internet, WiFi,

The DB server 130 stores the location information of the data concentrator (DCU) 120 and the first modem 111 to the Nth modem 11N and the power network information to construct a database (DB).

The distribution GIS (Geographic Information System) system 140 accesses the DB server 130 through the wireless network 10 to fetch the updated location information and the power network information to construct a distribution map on a map in real time .

FIG. 2 illustrates a registration process between a PLC modem and a DCU according to an embodiment of the present invention. Referring to FIG.

First, the state and function of each configuration shown in Fig. 2 will be briefly described.

It is assumed that the first slave modem 111 and the second slave modem 112 have already been registered and the third slave modem 113 is in a state to start registration.

The master modem 121 is a modem installed in the data concentrator (DCU) 120, and has a master-slave relationship with the first to third slave modems 111 to 113.

The Simple Network Management Protocol (SNMP) Agent 122 is a software (S / W) running in the data concentrator (DCU) 120 and periodically stores various information This is a protocol for automatically collecting and managing the network.

Hereinafter, the registration process between the third slave modem 113 and the data concentrator (DCU) 120 according to the present invention will be described with reference to FIG.

First, when the third slave modem 113 is turned on, the third slave modem 113 transmits a registration request packet (CJR, Cell Join Request) to the master modem 121 to request registration of a new modem Perform the notification process.

Table 1 below summarizes the structure of the CJR packet and the information related thereto.

Referring to Table 1, the CJR packet field includes O_SID, RP_SID, NPL, SN, CJRT, DT, MGWT, POS_X, POS_Y, MID, PM_V and LK_SPD.

In the case of the present invention, POS_X and POS_Y, which include the location information of the modem to be registered, are applied and when the third slave modem 113 first registers its location information to the DCU 120, The DCU 120 transmits the received location information to the DB server 130 so that the distribution GIS system 140 allows the location of the third slave modem 113 on the remote GIS three- Can be displayed automatically.

Next, the master modem 121 sends a packet called CIRQ to the third slave modem 113 to check the link of the third slave modem 113. [

Next, the third slave modem 113 transmits a packet called CIRP to the master modem 121 in response thereto.

Next, the SNMP Agent 122 of the data concentrator 120 receives the NDEMAND / CELLJOIN request of the third slave modem 113 transmitted through the master modem 121, and then performs the remaining registration process .

On the other hand, when the first slave modem 111 and the second slave modem 112 are already registered in the data concentrator (DCU) 120, the packet of the third slave modem 113 is transmitted to the first slave modem The first slave modem 111 or the second slave modem 112 can transmit the packet via a repeater, and in this case, the same registration process as described above is performed. (See S100)

This is because the conventional PLC modem for low-voltage remote meter-reading performs communication by selecting only a signal of a specific path among all the path signals transmitted to the data concentrator (DCU), whereas in the present invention, each of the slave modems 111 to 113, The connection state of the distribution route can be displayed on the GIS map through all route data information coming from the data concentrator 120 to the intelligent distribution system.

Next, the NMS (Network Management Station) Agent program of the master modem 121 transmits the NRETURN / CELLJOIN request packet to the third slave modem 113 in response to the CJR packet of the third slave modem 113 .

Next, the third slave modem 113 has a process of transmitting the NCOMMAND / Request NEP packet to the NMS Agent of the data concentrator (DCU 120).

Next, the Network Management Station (NMS) Agent program of the data concentrator 120 transmits the NCONFIRM / Request NEP packet to the third slave modem 113 in response to the above process. (See S200)

When the above steps S100 and S200 are completed, the third slave modem 113 is registered in the master modem 121 of the data concentrator (DCU) 120, and is ready for communication with other communication devices.

Meanwhile, since the registration, the status information of the third slave modem 113 is periodically transmitted to the SNMP Agent 122 of the data concentrator (DCU) 120 and the third slave modem 113 by sending and receiving the SYS.CONFIG packet, (Step S300). In the case where the registration has been made for the first time, it is performed indispensably. However, if the registration has already been performed, the step is selectively performed whenever necessary.

And if necessary, periodically transmitting a SYS.CONFIG.Setting packet between the SNMP Agent 122 of the data concentrator 120 and the third slave modem 113. (See S400)

That is, the data concentrator 120 periodically exchanges status information with the slave modem (for example, 900 seconds), updates the related information by continuously transmitting the slave modem and its information to the DB server 130 update.

Thus, the DB server 130 continuously updates and updates the information, and the distribution GIS system 140 periodically takes the information and configures the distribution on a three-dimensional map. do.

FIG. 3 shows an example in which the PLC modems registered according to the registration procedure of FIG. 2 are displayed on the layout of the three-dimensional GIS.

Referring to FIG. 3, the PLC modems registered in accordance with the registration procedure of FIG. 2 are automatically displayed on a three-dimensional GIS map, in which the DCU and the power network are formed (all paths are displayed in red) .

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit of the invention.

110:
111 to 11N: First to Nth Modems
120: Data Concentrator (DCU)
130: DB server
140: Distribution GIS system
10: Wired and wireless network

Claims (3)

A modem unit including a first slave modem for sending a registration request packet (CJR) through power line communication (PLC) to request an initial registration process and a second slave modem already registered;
A data concentrator (DCU) including a master modem and an SNMP agent for receiving the registration request packet transmitted by the first slave modem and processing a registration procedure;
A DB server for receiving location information and power grid information of the first slave modem or the second slave modem transmitted from the data concentrator (DCU) through a wired / wireless network, storing and updating the received location information and power grid information; And
And a distribution GIS system for periodically bringing the location information and the power network information from the DB server and displaying a distribution plan on a three-dimensional GIS map in real time. The method of claim 1, wherein the registration request packet (CJR)
And a POS_X field and a POS_Y field including position information of the first slave modem. 2. The system of claim 1, wherein the first slave modem comprises:
Directly transmits the registration request packet (CJR) to the master modem,
Or transmits the registration request packet (CJR) to the master modem via the second slave modem via a repeater.

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